System and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management

ABSTRACT

This is a system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management. The present invention relates to the improvement of integration and management of renewable electric energy in homes and small businesses. The invention offers a lower cost method for safely installing and managing the use of the electric energy either generated or stored onsite by solar collecting panels, wind turbine generators, backup hydrocarbon fueled generators or any other supplemental power sources such as fuel cells and future electric automobiles with smart energy management. Furthermore, the invention utilizes wireless controllers connected to key appliances, motors and systems permitting continuous real time load and energy management of these devices.

FIELD OF THE INVENTION

The present invention relates to the renewable alternative energy industry and, more particularly to, a system and method for lowering the cost of installation and better controlling the operation and management of a grid-tied inverter/controller for solar collectors, wind turbine generators, back-up generators or any other supplemental power source or energy system that could be used to power your home or small business. The present invention further relates to, a method of controlling load management during peak demand periods and in the event of a power outage.

BACKGROUND OF THE INVENTION

Traditionally, electric utilities have supplied home owners and businesses with electric energy. As the demand for electric power has increased so has the environmental awareness of the pollutants that are created in generating the electricity to meet the growing demand.

While there are many efforts to develop renewable sources of electric energy all across the United States, most of these commercial scale projects still are confronted with the same complexities as developing traditional centralized generation facilities such as coal or nuclear power plants.

The biggest issue facing any type of new centralized generation is how to transmit the generated electricity to the customer who is using it? Today, in the US, almost all of the large capacity electric transmission lines are operating at their maximum safe capacity and in other cases are old and need to be replaced. This leaves the utility companies in an increasingly difficult situation for continuing to meet the increasing demand for electrical energy.

This situation is driving the utilities to look at new ideas they have never before considered. One of these is the concept of Micro Distributed Renewable Generation. Simply put, this means locating renewable forms of electric energy generation at the point where the energy is being used instead of transmitting the energy long distances from a centralized generation location.

The concept of Micro Distributed Renewable Generation is also attracting the attention of an increasing number of home and small business owners in addition to the utilities as owner operators. Using a Micro Distributed Renewable Generation system Intelligent Renewable Energy System a device called an inverter. An inverter conditions the generated electricity into a form of electricity useable by the electric appliances in a home or small business. (AC alternating current)

A Micro Distributed Renewable Generation can be used either with or without connecting the inverter to the utility company power system, grid-tied and off-grid respectively. The primary benefit of grid-tied operation is that any generated energy that is not consumed in the home or business will be routed back to the utility company and serve to spin the owner's electric meter backward reducing the amount of purchased electricity from the utility company (net metering). In the event the owner-operator of the Micro Distributed Renewable Generation grid-tied system is a utility company the system becomes an energy resource to the utility.

The evolution of the Internet and networked information shared across the Internet (IP Networking) has made it possible to intelligently manage not only the generation of electricity but also the use of it. By combining the grid-tied Micro Distributed Renewable Generation inverter with IP networking it is possible to now monitor and automatically manage a home or small business's energy resources in accordance with either accepted practices or by owner preferences or both.

The management of electric energy usage occurs at two levels.

The first level is just an overall reduction in the number of appliances running and consuming energy. Turning them off, running them for shorter periods of time, cycling them less frequently all contribute to less electricity being used.

The second level is to control when appliances start. Getting a train car rolling from a dead stop requires more energy than keeping it rolling. The same is true when starting appliances. An air conditioner, pool pump, washing machine etc, all require a higher level of energy to start than required for normal operation. If multiple appliances all start at the same time there is an instant where there is an elevated requirement in the demand for electric energy (Peak Load).

While this peak demand only lasts for a moment, it Intelligent Renewable Energy System that sufficient power generation be available to meet this momentary demand. Power utilities are often challenged in trying to meet peak demands especially during certain seasons, hours of the day and areas of the country. Often times, utilities are not able to keep up. This results in what is commonly referred to as “Brown Outs” or where supply is not sufficient to meet demand. By controlling the starting and stopping of appliances peak demand can be reduced or even eliminated in some cases. (Intelligent

Micro Distributed Load Management)

The concept of Micro Distributed Renewable Generation coupled with Intelligent Micro Distributed Load Management has introduced the opportunity for both a near term and long term contribution to the goal of reaching the nationally stated objective of generating 20% or the US electrical energy needs through renewable resources.

As more and more manufacturers introduce solar and wind generation systems the cost of the systems are becoming more affordable. What has not been addressed and is not becoming more affordable are the labor costs associated with installing Micro Distributed Renewable Generation systems with grid-tied inverters. The average cost to install a typical system large enough to power a few circuits of a 1000 square foot home or small business is $5,000 or more. Most of this cost is the time consuming wiring involved with connection of the grid-tied inverter to the circuit breaker panel and the generation devices.

While new construction offers simplified access for wiring, the labor is still significant. Existing structures interject a multitude of complexities that all add labor costs to the installation. This includes coordination with owners for access, drilling holes in walls, pulling intelligent Renewable Energy System through hard to reach places, clean up and finishing work to restore the interior decor of the home or small business.

Current market grid-tied inverters are not designed to support more than a small number of isolated circuits in the home or small business. These designs often require expensive specialized isolation devices that turn off or disconnect the inverter from the street utility power in the event of a power outage. Additionally, inverters today are either designed for use with solar panels or wind turbines but not a combination of both.

For there to be a viable, low cost, widely adopted Micro Distributed Renewable Generation and Intelligent Micro Distributed Load Management system using a grid-tied inverter, the system will need to be simple, intuitive, and deploy a Low Cost Installation Process (LCIP) The system will need to offer value to both the home and small business owner, utility companies and demonstrate a high level of environmental stewardship. The system must be available to buyers on a turnkey basis, requiring no involvement of the buyer in the installation process or ongoing maintenance and servicing. The system must be self reporting and support automated operations.

It is this Micro Distributed Renewable Generation, Intelligent Micro Distributed Load Management, grid tied inverter and LCIP system and methods that is within this present invention.

SUMMARY OF THE INVENTION

This is a system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management. The present invention relates to the improvement of integration and management of renewable electric energy in homes and small businesses. The invention offers a lower cost method for safely installing and managing the use of the electric energy either generated or stored onsite by solar collecting panels, wind turbine generators, backup hydrocarbon fueled generators or any other supplemental power sources such as fuel cells and future electric automobiles with smart energy management. Furthermore, the invention utilizes wireless controllers connected to key appliances, motors and systems permitting continuous real time load and energy management of these devices.

It would be advantageous to provide a grid-tied inverter system that could be installed with a single plug on the exterior of the building and in turn reducing the cost of that installation

It would also be advantageous to provide a system that could improve the performance of the inverter by adding independent maximum power point tracking to that inverter.

It would further be advantageous to provide a system that is multi tap, multi mode so multiple input power devices can be used with a single inverter.

It would further be advantageous to provide a system a wireless system for real time smart load management with an internet interface for system owner input.

BRIEF DESCRIPTION OF THE DRAWINGS

A complete understanding of the present invention may be obtained by reference to the accompanying drawings, when considered in conjunction with the subsequent, detailed description, in which:

FIG. 1 is a perspective view of a typical meter box and meter with power mast, used on most residential and small commercial buildings;

FIG. 2 is a perspective view of an of the system for single plug-in installation of a high voltage grid-tied inverter with smart load management showing the major components of the system;

FIG. 3 is a perspective view of an installation process showing step one;

FIG. 4 is a perspective view of an installation process showing step two;

FIG. 5 is a perspective view of an installation process showing step three;

FIG. 6 is a perspective view of an installation process showing step four;

FIG. 7 is a perspective view of an installation process showing step five;

FIG. 8 is a perspective view of an installation process showing step six;

FIG. 9 is a perspective view of a meter jumper plug, a key element of the present invention;

FIG. 10 is an exploded view of a meter jumper plug;

FIG. 11 is a perspective view of a custom meter jumper wire harness, a further key element of the present invention;

FIG. 12 is a flow chart view of a typical flow of electricity from utility company to service panel;

FIG. 13 is a flow chart view of a flow of electricity in accordance with the present invention from utility company to main service panel; and

FIG. 14 is a perspective view of a completed system and method for single plug-in installation of a high voltage grid-tied inverter with smart load management mounted together with existing building components.

For purposes of clarity and brevity, like elements and components will bear the same designations and numbering throughout the Figures.

Description of the Preferred Embodiment

Before explaining the disclosed embodiment of the present invention in detail it is to be understood that the invention is not limited in its application to the details of the particular arrangement shown since the invention is capable of other embodiments. Also, the terminology used herein is for the purpose of description and not of limitation.

FIG. 1 is a perspective view of a typical meter box and meter with power mast 23, used on most residential and small commercial buildings. This is considered a typical installation on most homes and small commercial buildings in the United States. This embodiment includes a power line 22 coming from the electric utility; this power line 22 is attached to a meter receiver box 21 through a mast 23 that is serviced from overhead or underground. The existing meter 20 is plugged into the meter receiver box 21 thus completing the connection so the electricity from the power line 22 can then feed through the existing meter 20 on into the main service panel 68.

FIG. 2 is a perspective view of the system for single plug-in installation of a high voltage grid-tied inverter with smart load management showing the major components of the system. A primary goal of the present invention was to provide a grid-tied inverter system that could be installed with a single plug on the exterior of the building and in turn reducing the cost of that installation. To that goal the meter jumper plug 24 was invented, detailed descriptions are discussed in FIGS. 9 and 11. This meter jumper plug 24 is installed in the meter receiver box 21 replacing the existing meter 20, intern rerouting the power line 22 to the new system meter socket 26 located in the weather tight custom cabinet 32 that houses all the components of the present invention's high voltage grid-tied inverter.

Within the weather tight custom cabinet 32 is the system meter socket 26, the intelligent Renewable Energy System from the custom wire harness 25 come from the meter jumper plug 24 to the system meter socket 26 and then into the main breaker 27, a code compliance for a cutoff directly behind the existing meter 20. From there the power moves through the electronic transfer isolation switch 28, a switch that electronically senses the loss of power line 22 and disconnects the building from the power line 22. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the power line 22. When the power line 22 is restored by the utility, the electronic transfer isolation switch 28 electronically synchronizes and reconnects the building with the power line 22 automatically. This is also the point where the electric load from the renewable sources enters the buildings power system. From this point the go the intelligent Renewable Energy System go back to the meter receiver box 21 on the existing building. Resulting in the existing meter 20 now being located in the weather tight custom cabinet 32.

Further contained in the weather tight custom cabinet 32 is the multi mode inverter/converter 29 with a multi mode inverter/converter control panel 30. This multi mode inverter/converter 29 is unique in that it will work with multiple input renewable devices simultaneously. Previously a separate inverter was needed to control different source renewable such as one for solar and a different one for wind. With our integrated micro processor we can control the input voltage and run multiple renewable sources simultaneously. Additional improvements to prior art is the micro processor controlled independent maximum power point tracking for both wind turbine 73 and solar cells 70. By incorporating maximum power point tracking directly onto the multi tap converter improves the overall performance and allows for more efficient use of the renewable input sources.

With the evolution of the Internet and networked information shared across the Internet (IP Networking) has made it possible to intelligently manage not only the generation of electricity but also the use of it. By combining the grid-tied inverter with IP networking it is possible to now monitor and automatically manage a home or small business's energy resources in accordance with either accepted practices or by owner preferences or both. To this means an RF module and Internet module 31 has been added to the micro processor with a programmable DSP, combining this with the remote load management modules 80 allows the management of electric energy usage to occur at two levels. The first level is just an overall reduction in the number of appliances running and consuming energy. This is accomplished by the remote load management modules 80 being plugged into multiple appliances, motors and other high load electrical devices, the remote load management modules 80 communicate with the DSP processor in real time relaying the load and use information of the system they are plugged into. They can then use this information to turn them off, run them for shorter periods of time, cycling them less frequently. Doing it this way will contribute to less electricity being used.

The second level is to control when appliances start. Getting a train car rolling from a dead stop requires more energy than keeping it rolling. The same is true when starting appliances. An air conditioner, pool pump, washing machine etc, all require a higher level of energy to start than required for normal operation. If multiple appliances all start at the same time there is an instant where there is an elevated requirement in the demand for electric energy (Peak Load). This peak load can be managed by the remote load management modules 80 relaying the need to start the motor to the DSP, the processor then checks the system for other load request. If none are present the remote load management module will be instructed to allow the motor start, if there is a conflict with another request for load one of the request will be delayed buy the system until the first motor is started and completely up to speed. Then the remote load management modules 80 will be instructed to start the next motor and so on.

Also contained within the weather tight custom cabinet 32 in a separate compartment on the bottom of the cabinet is an energy input wiring bus 34 this is where the renewable energy sources are wired to the system. Directly above the energy input wiring bus 34 are a row of feed in breakers 36 so that all input of renewable energy sources or storage devices can be shut down for maintenance. The main energy source cable 35 for the wind turbine 73 and solar cells 70 is also routed through the energy input wiring bus 34. Next to the row of feed in breakers 36 is a system programming port 37, this port is primarily used buy the installer to program the remote load management modules 80 and other functions that need to be set at installation. This port will accept both USB and Ethernet cables.

Furthermore, there is a heat sink 33 on the back of the weather tight custom cabinet 32 to dissipate the waste heat given off by the inverter and converter. Also a custom mounting bracket 38 specifically designed so one person can install the system, simple use the light weight template supplied with the system to install the hanging bracket to the wall then drop the system over the mounting pegs and lock in place with the lock down screws. The present invention is also configured to be a standalone system, on the top of the weather tight custom cabinet 32; just above the system meter socket 26 is a water proof cap 39. When the water proof cap 39 is removed a standard mast 23 can be mounted and the power line 22 can be installed directly on the present invention, the meter jumper plug 24 and the custom wire harness 25 can be removed so the power line 22 can be run from the utility power line 22 through the present invention and then directly into the main service panel 68. Thus allowing the present invention to be a completely stand alone system for new construction and remodels.

FIG. 3 is a perspective view of the installation process showing step one. Step one is locating the existing meter 20 and meter receiver box 21. Then making sure that there is room for the system installation, clear out anything that is in the way and set-up to mount the template for the mounting system, mount the brackets for the system on the wall in close proximity to the existing meter 20 receiver.

FIG. 4 is a perspective view of the installation process showing step two. Step two is removing the system from its packaging and hang it on the mounting bracket 38 that was installed on the wall in step one. Lock down the safety screws so the system will not come off the mounting brackets. Connect the main energy source cable 35 from the wind turbine 73 and solar cells 70 and connect any optional source loads such as battery storage 71 or auxiliary gas generator 74.

FIG. 5 is a perspective view of the installation process showing step three. Step three is removing the existing meter 20 from the meter receiver box 21.

FIG. 6 is a perspective view of the installation process showing step four. Step four is plugging the meter jumper plug 24 into the existing meter receiver box 21.

FIG. 7 is a perspective view of the installation process showing step five. Step five is plugging the existing meter 20 into the system meter socket 26.

FIG. 8 is a perspective view of the installation process showing step six. Step six is plugging the remote load management modules 80 into multiple appliances, motors and other high load electrical devices. Then the installer plugs his computer into the system programming port 37 and programs the remote load management modules 80 and activates the smart load management feature and web management power control center. At this point turn on the feed in breakers 36 and the main breaker 27. The system automatically synchronizes and begins producing electric power, testing itself and reporting real time data through the Internet.

FIG. 9 is a perspective view of the meter jumper plug 24, a key element of the present invention. The meter jumper plug 24 is the key element of the present invention that makes it fast and simple to install the system to a home or small business. The meter jumper plug 24 comprises a plug base 40 of similar size to the existing meter 20, the plug base 40 is made from injection molded non-conductive plastic with guide blocks 41 molded in the base for quick and safe plug in. There is a non-conductive plastic injection molded meter plug cover 52 of similar size and shape of the existing meter 20 that is held in place with cover screw 55. On the meter plug cover 52 is the main wire port 53 with a wire locking ring 54. From this view you can clearly see the knife blades from the power blade block 50, these knife blades fit into the meter receiver box 21 to make the connections for the power line 22 to flow through the system.

FIG. 10 is an exploded view of the meter jumper plug 24. This view shows the interior parts of the meter jumper plug 24. Molded in the plug base 40 is blade seat 42 and ground seat 43 these securely hold the power blade block 50 and the ground block 48 in place and adds a margin of insulation between the blocks. Furthermore, molded in the plug base 40 are locator strips for the ground transfer strap 44. The ground transfer strap 44 is held in place with the transfer strap screw 45 that is taped into the ground block 48. On the end of the ground transfer strap 44 is the ground clamp 46 with clamp screw 47, this is used to attach the ground wire 56 to the existing meter receiver box 21. The intelligent Renewable Energy System from the custom wire harness 25 is securely held in place with the blade block screw 51 and the ground block screw 49.

FIG. 11 is a perspective view of a custom meter jumper wire harness, a further key element of the present invention. The custom wire harness 25 is comprised of copper or aluminum wire rated at 200 amps, there is a ground wire 56 and four power intelligent Renewable Energy System, power wire 1 57 is a load wire from the power line 22, power wire 2 58 is the second load wire from the power line 22, power wire 3 59 is the return load wire to the main service panel 68 and power wire 4 60 is the second load wire to the main service panel 68.

FIG. 12 is a flow chart showing typical flow of electricity from utility company to service panel. This flow chart is to show prior art or standard residential or small business existing system.

FIG. 13 is a flow chart showing flow of electricity In accordance with the present invention from utility company to main service panel 68. This drawing demonstrates the flow of electricity and technology of the present invention. The flow in starts at the utility electric service/grid access 61 into the existing meter 20 receiver and out the meter jumper plug 24 to the system meter socket 26, this is the meter flow path 62. The existing meter 20 is moved to the system meter socket 26 and connected to the service disconnect breaker, this is the disconnect flow path 63. Having this breaker directly behind the meter makes this system electric code compliant.

This next connection is between the service disconnect breaker and the electronic transfer isolation switch 28; this is the isolation flow 64. This is the flow that would be automatically disconnected in a power line 22 outage to isolate the renewable power supply from the grid or if you wanted to operate off the utility electric service/grid access 61 and only use the grid for your own backup system. This flow can be switched on and off from the web interface.

The electronic transfer isolation switch 28 is the point where all power produced by renewable sources and power storage devices is transferred to the building to be used or sold back the grid. This connection is called the power switching flow 65. Once the power crosses the power switching flow 65 it is either run back through the existing meter 20 and into the main service panel 68, this is the main service flow 67 or in the event of a power line 22 failure the existing meter 20 is bypassed and the power flow is through the electronic transfer isolation switch 28 on then to the main service panel 68, this is the electronic transfer flow 66.

Renewable power for the system can be supplied by numerous sources simultaneously due to the processor controlled multi tap converter with independent maximum power point tracking. This power can come from the solar cells 70 and wind turbine 73 that are supplied with the system or from an auxiliary gas generator 74. Future power supplies may come from using an electric car as a storage device. The system can charge the electric during off peak times and then use the power during peak periods; this would be the future electric car flow 69. Another embodiment may be power from a fuel cell 72 or optional battery storage 71.

Once the renewable energy is collected by the multi tap converter it is transferred to the multi mode inverter through the DC Bus 75. The multi mode inverter is a processor controlled inverter that will take input from multiple input devices and simultaneously convert that input to 240 volt 60 cycle AC output, this is the inverter flow 76. Once the power is cleaned it is transferred to the power control circuits 77 for distribution to either the main service panel 68 or if it is not needed it will then be sold back to the utility electric service/grid access 61.

All this process is being controlled by the 32 bit micro processor with DSP; this is illustrated by the micro processor control flow 78. The final embodiment of the present invention is the RF and Internet communication link 79. This link controls all the communication aspects of the system; this includes the remote load management modules 80 and the web base user interface.

FIG. 14 is a perspective view of the completed system and Method for single plug-in installation of a high voltage grid-tied inverter with smart load management mounted together with existing building components. This is perspective view of a completed intelligent renewable energy system grid-tied controller components showing all visible embodiments of the present invention.

Since other modifications and changes varied to fit particular operating requirements and environments will be apparent to those skilled in the art, the invention is not considered limited to the example chosen for purposes of disclosure, and covers all changes and modifications which do not constitute departures from the true spirit and scope of this invention.

Having thus described the invention, what is desired to be protected by Letters Patent is presented in the subsequently appended claims. 

1. A system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management for simplifying the installation and in turn reducing the cost of that installation. Improving the performance by adding independent maximum power point tracking to the inverter. Making a system that is multi tap, multi mode so multiple input power devices can be used with a single inverter. Creating a wireless system for real time smart load management with an internet interface for system owner input, comprising: 1.1 Means for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings; 1.2 Means for junction box between electric utility and main electric panel that houses the meter receiver and main cutoff of power from electric utility; 1.3 Means for transfer of electric power to and from the utility company; 1.4 means for redirecting or transferring the main power line flow from the meter receiver box through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter receiver box and into the main service panel, rigidly connected to said means for junction box between electric utility and main electric panel that houses the meter receiver and main cutoff of power from electric utility; 1.5 means for to facilitate the redirecting or transferring the main power line flow from the meter jumper plug through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter jumper plug and into the main service panel, rigidly connected to said means for redirecting or transferring the main power line flow from the meter receiver box through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter receiver box and into the main service panel; 1.6 means for creating a point or position on the Intelligent Renewable Energy System unit to relocate the existing meter too, once the power transfer is complete, rigidly connected to said means for to facilitate the redirecting or transferring the main power line flow from the meter jumper plug through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter jumper plug and into the main service panel, and rigidly connected to said means for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings; 1.7 means for to create a main cutoff of power directly behind the existing meter once moved to the new location on the Intelligent Renewable Energy System, rigidly connected to said means for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings; 1.8 Means for electronically sensing the loss of street power and disconnects the building from the utility power line. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the utility power line. when the utility power line is restored the system electronically synchronizes and reconnects the building with the utility power line automatically, rigidly connected to said means for to create a main cutoff of power directly behind the existing meter once moved to the new location on the Intelligent Renewable Energy System; 1.9 means for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 1.10 means for multi function keypad with LED display for programming features and checking system status, rigidly connected to said means for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 1.11 means for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface; 1.12 means for making the multi mode inverter/converter system weather tight for installation on the exterior of the building, rigidly connected to said means for creating a point or position on the Intelligent Renewable Energy System unit to relocate the existing meter too, once the power transfer is complete; 1.13 means for absorbing then dissipating the heat created by the systems electronic components, rigidly connected to said means for making the multi mode inverter/converter system weather tight for installation on the exterior of the building; 1.14 means for mounting the intelligent Renewable Energy System necessary for adding energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.15 Means for supplying input electric energy from the solar array and wind turbine that is remotely mounted on the roof of the building; 1.16 Means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.17 Means for system programming, onsite updates and maintenance by the certified installers; 1.18 means for mounting the system to the wall with sufficient stand off so the heat sink will function properly, rigidly connected to said means for making the multi mode inverter/converter system weather tight for installation on the exterior of the building; 1.19 Means for creating a weather tight cap over the pole mounting hole that converts the system to a standalone system for new construction installations; 1.20 Means for creating the base for which all other elements of the meter jumper plug are mounted too; 1.21 Means for guiding the meter jumper plug into place during an installation; 1.22 Means for creating a secure mounting position for the power blade elements; 1.23 Means for creating a secure mounting position for the ground block element; 1.24 Means for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.25 Means for connecting the ground transfer strap to the ground block for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.26 means for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.27 means for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.28 means for creating a connection point within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.29 means for securing the wire within the ground screw block within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 1.30 Means for facilitating within the meter jumper plug in transferring the power wire to and from the meter receiver box to and from the system meter socket; 1.31 means for securing the wire in the power blade block within the meter jumper plug facilitating transferring the power wire to and from the meter receiver box to and from the system meter socket; 1.32 Means for creating weather tight seal and cover over the components of the meter jumper plug; 1.33 Means for attaching the custom wire harness to the meter jumper plug; 1.34 Means for locking the custom wire harness to the meter jumper plug; 1.35 Means for securing the meter plug cover to the plug base; 1.36 Means for transferring ground wire from the meter receiver box through meter plug to and from the service meter socket; 1.37 Means for transferring power wire 1 from the meter receiver box through meter plug to and from the service meter socket; 1.38 Means for transferring power wire 2 from the meter receiver box through meter plug to and from the service meter socket; 1.39 Means for transferring power wire 3 from the meter receiver box through meter plug to and from the service meter socket; 1.40 Means for transferring power wire 4 from the meter receiver box through meter plug to and from the service meter socket; 1.41 Means for showing the transferring of electricity to and from the electric utility grid, rigidly connected to said means for transfer of electric power to and from the utility company; 1.42 Means for demonstrating the two directional flows of electricity coming and going from the utility service through the meter jumper plug to the relocated meter in the system meter socket; 1.43 Means for demonstrating the two directional flows of electricity coming and going from the relocated meter in the system meter socket to the service disconnect breaker; 1.44 Means for demonstrating the two directional flows of electricity coming and going from the service disconnect breaker to the isolation switch; 1.45 Means for demonstrating the two directional flows of electricity coming and going from the isolation switch to the electric power coming from the inverter system; 1.46 means for demonstrating the one directional flow of electricity coming from the electronic transfer switch after it has electronically since a loss of power from the utility electric service/grid in turn isolating the grid from power being produced by the generation system; 1.47 Means for demonstrating the one directional flow of electricity coming from the utility service and the generation system through the meter jumper plug to the main service panel; 1.48 means for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an electric car, showing how the system can not only charge the electric car but can use the electric car as a power storage device, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.49 means for showing the flow of electricity from one of the primary renewable energy sources to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.50 means for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an battery storage system, showing how the system can not only charge the battery but can also use the battery as a power storage device, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.51 means for demonstrating the future two directional flow of electricity coming from and going to a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and a fuel cell, showing how the system can not only charge the fuel cell but can use the fuel cell as a power storage device, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.52 means for showing the flow of electricity from one of the primary sources of renewable energy through a rectifier and then into the multi tap converter, a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.53 means for showing the flow of electricity going from the auxiliary gas generator through the rectifier and into the multi mode inverter, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 1.54 means for demonstrating the two directional flow of electricity coming from and going to the multi tap converter and the high voltage dc bus, rigidly connected to said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system, and rigidly connected to said means for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 1.55 means for showing the flow from the high voltage dc bus to the processor controlled multi mode inverter that converts the dc power to 240 v 60 cycle ac output for use in the building or for sale to the utility electric service/grid; 1.56 means for showing the flow of electricity from the inverter to the processor controlled electronic power switching and regulation circuits, rigidly connected to said means for multi function keypad with LED display for programming features and checking system status, and rigidly connected to said means for electronically sensing the loss of street power and disconnects the building from the utility power line. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the utility power line. When the utility power line is restored the system electronically synchronizes and reconnects the building with the utility power line automatically; 1.57 means for showing the two way communicating and controlling of the micro processor to and from the electronic power switching and regulation circuits, multi mode inverter, high voltage bus, multi tap converter and rectifier and all other processor controlled functions not listed, rigidly connected to said means for showing the flow of electricity from the inverter to the processor controlled electronic power switching and regulation circuits, rigidly connected to said means for system programming, onsite updates and maintenance by the certified installers, rigidly connected to said means for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface, rigidly connected to said means for multi function keypad with LED display for programming features and checking system status, and rigidly connected to said means for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 1.58 means for showing the link between the micro processor to the internet communications link that automatically self connects to web management power control center for onsite load and energy management also showing the connection with the RF transceiver that sends and receives load management information to the remote load management modules; and 1.59 means for communicating and control the load management remote monitor/controller units that would be connected to key appliances, motors and systems within to be connected to key appliances, motors and systems within the building by an RF transmitter permitting continuous load and energy management of these devices by sending and receiving commands from the micro processor for the starting and stopping of the controlled devices, rigidly connected to said means for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface.
 2. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings comprises a standard meter used in most residential and small commercial buildings existing meter.
 3. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for junction box between electric utility and main electric panel that houses the meter receiver and main cutoff of power from electric utility comprises a junction box between electric utility and main electric panel, houses the meter receiver and main cutoff of power from electric utility meter receiver box.
 4. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transfer of electric power to and from the utility company comprises a main power line coming from utility power line.
 5. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for redirecting or transferring the main power line flow from the meter receiver box through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter receiver box and into the main service panel comprises a redirects or transfers main power line flow through grid-tie controller meter socket, can be used in standard meter receiver box, will work with both 100 and 200 amp service, is weather tight and fully serviceable meter jumper plug.
 6. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for to facilitate the redirecting or transferring the main power line flow from the meter jumper plug through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter jumper plug and into the main service panel comprises a rated for 200 amps, stranded wire for maximum flexibility, soldered end caps for maximum current conductivity, all weather fittings and cover custom wire harness.
 7. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a point or position on the Intelligent Renewable Energy System unit to relocate the existing meter too, once the power transfer is complete comprises a work with existing meter, fully lockable isolated from other wiring, work as a standalone application on new construction, does not change the procedure or method for utilities to read the meter system meter socket.
 8. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for to create a main cutoff of power directly behind the existing meter once moved to the new location on the Intelligent Renewable Energy System comprises a will work with either 100 or 200 amp service main breaker.
 9. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for electronically sensing the loss of street power and disconnects the building from the utility power line. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the utility power line. when the utility power line is restored the system electronically synchronizes and reconnects the building with the utility power line automatically comprises an automatically senses loss of power, automatically disconnects the house from utility power line, automatically reconnects the house to the utility power line, electronically synchronizes when reconnecting the utility power line, automatically displays state of the system electronic transfer isolation switch.
 10. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid comprises a processor controlled ac to dc rectifier, processor controlled dc to dc multi-tap converter, processor monitored independent maximum power point tracking, processor monitored high voltage dc bus, processor controlled multi mode inverter with 400 v dc input 240 v 60 cycle ac output, processor controlled electronic power switching and regulation circuits, programmable micro processor, DSP controller board, internet communications module, DSP controlled RF transceiver multi mode inverter/converter.
 11. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for multi function keypad with LED display for programming features and checking system status comprises a multi mode inverter/converter control panel.
 12. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface comprises a Wi-Fi, wireless, Bluetooth and Zigbee enabled RF module and internet module.
 13. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for making the multi mode inverter/converter system weather tight for installation on the exterior of the building comprises a weather tight, lockable weather tight custom cabinet.
 14. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for absorbing then dissipating the heat created by the systems electronic components comprises an aluminum alloy extrusion heat sink.
 15. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for mounting the intelligent Renewable Energy System necessary for adding energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system comprises a zinc coated copper or aluminum energy input wiring bus.
 16. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for supplying input electric energy from the solar array and wind turbine that is remotely mounted on the roof of the building comprises a custom cable with ground main energy source cable.
 17. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system comprises a ground fault, electronically monitored feed in breakers.
 18. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for system programming, onsite updates and maintenance by the certified installers comprises an USB, Ethernet system programming port.
 19. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for mounting the system to the wall with sufficient stand off so the heat sink will function properly comprises a steel or aluminum mounting bracket.
 20. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a weather tight cap over the pole mounting hole that converts the system to a standalone system for new construction installations comprises a steel with rubber gasket water proof cap.
 21. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating the base for which all other elements of the meter jumper plug are mounted too comprises a non-conductive plastic plug base.
 22. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for guiding the meter jumper plug into place during an installation comprises a non-conductive plastic guide blocks.
 23. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a secure mounting position for the power blade elements comprises a non-conductive plastic blade seat.
 24. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a secure mounting position for the ground block element comprises a non-conducting plastic ground seat.
 25. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal ground transfer strap.
 26. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for connecting the ground transfer strap to the ground block for facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal transfer strap screw.
 27. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal ground clamp.
 28. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal clamp screw.
 29. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a connection point within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal ground block.
 30. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for securing the wire within the ground screw block within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal ground block screw.
 31. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for facilitating within the meter jumper plug in transferring the power wire to and from the meter receiver box to and from the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal power blade block.
 32. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for securing the wire in the power blade block within the meter jumper plug facilitating transferring the power wire to and from the meter receiver box to and from the system meter socket comprises a zinc plated copper, aluminum, or some other highly conductive metal blade block screw.
 33. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for creating a weather tight seal and cover over the components of the meter jumper plug comprises a non-conductive plastic meter plug cover.
 34. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for attaching the custom wire harness to the meter jumper plug comprises a non-conductive plastic main wire port.
 35. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for locking the custom wire harness to the meter jumper plug comprises a non-conductive plastic wire locking ring.
 36. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for securing the meter plug cover to the plug base comprises a metal cover screw.
 37. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transferring ground wire from the meter receiver box through meter plug to and from the service meter socket comprises a copper, aluminum, or some other highly conductive metal ground wire.
 38. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transferring power wire 1 from the meter receiver box through meter plug to and from the service meter socket comprises a copper, aluminum, or some other highly conductive metal power wire
 1. 39. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transferring power wire 2 from the meter receiver box through meter plug to and from the service meter socket comprises a copper, aluminum, or some other highly conductive metal power wire
 2. 40. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transferring power wire 3 from the meter receiver box through meter plug to and from the service meter socket comprises a copper, aluminum, or some other highly conductive metal power wire
 3. 41. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for transferring power wire 4 from the meter receiver box through meter plug to and from the service meter socket comprises a copper, aluminum, or some other highly conductive metal power wire
 4. 42. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the transferring of electricity to and from the electric utility grid comprises an electricity coming in from the street or electricity being sold back to the utility power grid utility electric service/grid access.
 43. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming and going from the utility service through the meter jumper plug to the relocated meter in the system meter socket comprises a meter flow path.
 44. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming and going from the relocated meter in the system meter socket to the service disconnect breaker comprises a disconnect flow path.
 45. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming and going from the service disconnect breaker to the isolation switch comprises an isolation flow.
 46. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming and going from the isolation switch to the electric power coming from the inverter system comprises a power switching flow.
 47. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the one directional flow of electricity coming from the electronic transfer switch after it has electronically since a loss of power from the utility electric service/grid in turn isolating the grid from power being produced by the generation system comprises an electronic transfer flow.
 48. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the one directional flow of electricity coming from the utility service and the generation system through the meter jumper plug to the main service panel comprises a main service flow.
 49. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an electric car, showing how the system can not only charge the electric car but can use the electric car as a power storage device comprises an electric car flow.
 50. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the flow of electricity from one of the primary renewable energy sources to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously comprises a solar cells.
 51. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an battery storage system, showing how the system can not only charge the battery but can also use the battery as a power storage device comprises a battery storage.
 52. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the future two directional flow of electricity coming from and going to a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and a fuel cell, showing how the system can not only charge the fuel cell but can use the fuel cell as a power storage device comprises a fuel cell.
 53. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the flow of electricity from one of the primary sources of renewable energy through a rectifier and then into the multi tap converter, a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously comprises a wind turbine.
 54. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the flow of electricity going from the auxiliary gas generator through the rectifier and into the multi mode inverter comprises an auxiliary gas generator.
 55. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for demonstrating the two directional flow of electricity coming from and going to the multi tap converter and the high voltage dc bus comprises a dc bus.
 56. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the flow from the high voltage dc bus to the processor controlled multi mode inverter that converts the dc power to 240 v 60 cycle ac output for use in the building or for sale to the utility electric service/grid comprises an inverter flow.
 57. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the flow of electricity from the inverter to the processor controlled electronic power switching and regulation circuits comprises a power control circuits.
 58. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the two way communicating and controlling of the micro processor to and from the electronic power switching and regulation circuits, multi mode inverter, high voltage bus, multi tap converter and rectifier and all other processor controlled functions not listed comprises a micro processor control flow.
 59. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for showing the link between the micro processor to the internet communications link that automatically self connects to web management power control center for onsite load and energy management also showing the connection with the RF transceiver that sends and receives load management information to the remote load management modules comprises a RF and internet communication link.
 60. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management in accordance with claim 1, wherein said means for communicating and control the load management remote monitor/controller units that would be connected to key appliances, motors and systems within to be connected to key appliances, motors and systems within the building by an RF transmitter permitting continuous load and energy management of these devices by sending and receiving commands from the micro processor for the starting and stopping of the controlled devices comprises a Wi-Fi, wireless, Bluetooth and Zigbee enabled remote load management modules.
 61. A system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management for simplifying the installation and in turn reducing the cost of that installation. Improving the performance by adding independent maximum power point tracking to the inverter. Making a system that is multi tap, multi mode so multiple input power devices can be used with a single inverter. Creating a wireless system for real time smart load management with an internet interface for system owner input, comprising: 61.1 a standard meter used in most residential and small commercial buildings existing meter, for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings; 61.2 a junction box between electric utility and main electric panel, houses the meter receiver and main cutoff of power from electric utility meter receiver box, for junction box between electric utility and main electric panel that houses the meter receiver and main cutoff of power from electric utility; 61.3 A main power line coming from utility power line, for transfer of electric power to and from the utility company; 61.4 a redirects or transfers main power line flow through grid-tie controller meter socket, can be used in standard meter receiver box, will work with both 100 and 200 amp service, is weather tight and fully serviceable meter jumper plug, for redirecting or transferring the main power line flow from the meter receiver box through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter receiver box and into the main service panel, rigidly connected to said meter receiver box; 61.5 a rated for 200 amps, stranded wire for maximum flexibility, soldered end caps for maximum current conductivity, all weather fittings and cover custom wire harness, for to facilitate the redirecting or transferring the main power line flow from the meter jumper plug through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter jumper plug and into the main service panel, rigidly connected to said meter jumper plug; 61.6 a work with existing meter, fully lockable isolated from other wiring, work as a standalone application on new construction, does not change the procedure or method for utilities to read the meter system meter socket, for creating a point or position on the Intelligent Renewable Energy System unit to relocate the existing meter too, once the power transfer is complete, rigidly connected to said custom wire harness, and rigidly connected to said existing meter; 61.7 a will work with either 100 or 200 amp service main breaker, for to create a main cutoff of power directly behind the existing meter once moved to the new location on the Intelligent Renewable Energy System, rigidly connected to said existing meter; 61.8 an automatically senses loss of power, automatically disconnects the house from utility power line, automatically reconnects the house to the utility power line, electronically synchronizes when reconnecting the utility power line, automatically displays state of the system electronic transfer isolation switch, for electronically sensing the loss of street power and disconnects the building from the utility power line. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the utility power line. When the utility power line is restored the system electronically synchronizes and reconnects the building with the utility power line automatically, rigidly connected to said main breaker; 61.9 a processor controlled ac to dc rectifier, processor controlled dc to dc multi-tap converter, processor monitored independent maximum power point tracking, processor monitored high voltage dc bus, processor controlled multi mode inverter with 400 v dc input 240 v 60 cycle ac output, processor controlled electronic power switching and regulation circuits, programmable micro processor, DSP controller board, internet communications module, DSP controlled RF transceiver multi mode inverter/converter, for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 61.10 a multi mode inverter/converter control panel, for multi function keypad with LED display for programming features and checking system status, rigidly connected to said multi mode inverter/converter; 61.11 a Wi-Fi, wireless, Bluetooth and Zigbee enabled RF module and internet module, for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface; 61.12 a weather tight, lockable weather tight custom cabinet, for making the multi mode inverter/converter system weather tight for installation on the exterior of the building, rigidly connected to said system meter socket; 61.13 an aluminum alloy extrusion heat sink, for absorbing then dissipating the heat created by the systems electronic components, rigidly connected to said weather tight custom cabinet; 61.14 a zinc coated copper or aluminum energy input wiring bus, for mounting the intelligent Renewable Energy System necessary for adding energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 61.15 a custom cable with ground main energy source cable, for supplying input electric energy from the solar array and wind turbine that is remotely mounted on the roof of the building; 61.16 a ground fault, electronically monitored feed in breakers, for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 61.17 An USB, Ethernet system programming port, for system programming, onsite updates and maintenance by the certified installers; 61.18 a steel or aluminum mounting bracket, for mounting the system to the wall with sufficient stand off so the heat sink will function properly, rigidly connected to said weather tight custom cabinet; 61.19 a steel with rubber gasket water proof cap, for creating a weather tight cap over the pole mounting hole that converts the system to a standalone system for new construction installations; 61.20 A non-conductive plastic plug base, for creating the base for which all other elements of the meter jumper plug are mounted too; 61.21 A non-conductive plastic guide blocks, for guiding the meter jumper plug into place during an installation; 61.22 A non-conductive plastic blade seat, for creating a secure mounting position for the power blade elements; 61.23 A non-conducting plastic ground seat, for creating a secure mounting position for the ground block element; 61.24 a zinc plated copper, aluminum, or some other highly conductive metal ground transfer strap, for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.25 a zinc plated copper, aluminum, or some other highly conductive metal transfer strap screw, for connecting the ground transfer strap to the ground block for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.26 a zinc plated copper, aluminum, or some other highly conductive metal ground clamp, for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.27 a zinc plated copper, aluminum, or some other highly conductive metal clamp screw, for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.28 a zinc plated copper, aluminum, or some other highly conductive metal ground block, for creating a connection point within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.29 a zinc plated copper, aluminum, or some other highly conductive metal ground block screw, for securing the wire within the ground screw block within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 61.30 a zinc plated copper, aluminum, or some other highly conductive metal power blade block, for facilitating within the meter jumper plug in transferring the power wire to and from the meter receiver box to and from the system meter socket; 61.31 a zinc plated copper, aluminum, or some other highly conductive metal blade block screw, for securing the wire in the power blade block within the meter jumper plug facilitating transferring the power wire to and from the meter receiver box to and from the system meter socket; 61.32 A non-conductive plastic meter plug cover, for creating a weather tight seal and cover over the components of the meter jumper plug; 61.33 A non-conductive plastic main wire port, for attaching the custom wire harness to the meter jumper plug; 61.34 A non-conductive plastic wire locking ring, for locking the custom wire harness to the meter jumper plug; 61.35 A metal cover screw, for securing the meter plugs cover to the plug base; 61.36 a copper, aluminum, or some other highly conductive metal ground wire, for transferring ground wire from the meter receiver box through meter plug to and from the service meter socket; 61.37 a copper, aluminum, or some other highly conductive metal power wire 1, for transferring power wire 1 from the meter receiver box through meter plug to and from the service meter socket; 61.38 a copper, aluminum, or some other highly conductive metal power wire 2, for transferring power wire 2 from the meter receiver box through meter plug to and from the service meter socket; 61.39 a copper, aluminum, or some other highly conductive metal power wire 3, for transferring power wire 3 from the meter receiver box through meter plug to and from the service meter socket; 61.40 a copper, aluminum, or some other highly conductive metal power wire 4, for transferring power wire 4 from the meter receiver box through meter plug to and from the service meter socket; 61.41 an electricity coming in from the street or electricity being sold back to the utility power grid utility electric service/grid access, for showing the transferring of electricity to and from the electric utility grid, rigidly connected to said power line; 61.42 A meter flow path, for demonstrating the two directional flows of electricity coming and going from the utility service through the meter jumper plug to the relocated meter in the system meter socket; 61.43 A disconnect flow path, for demonstrating the two directional flow of electricity coming and going from the relocated meter in the system meter socket to the service disconnect breaker; 61.44 An isolation flow, for demonstrating the two directional flows of electricity coming and going from the service disconnect breaker to the isolation switch; 61.45 A power switching flow, for demonstrating the two directional flow of electricity coming and going from the isolation switch to the electric power coming from the inverter system; 61.46 an electronic transfer flow, for demonstrating the one directional flow of electricity coming from the electronic transfer switch after it has electronically since a loss of power from the utility electric service/grid in turn isolating the grid from power being produced by the generation system; 61.47 A main service flow, for demonstrating the one directional flow of electricity coming from the utility service and the generation system through the meter jumper plug to the main service panel; 61.48 an electric car flow, for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an electric car, showing how the system can not only charge the electric car but can use the electric car as a power storage device, rigidly connected to said feed in breakers; 61.49 a solar cells, for showing the flow of electricity from one of the primary renewable energy sources to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said feed in breakers; 61.50 a battery storage, for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an battery storage system, showing how the system can not only charge the battery but can also use the battery as a power storage device, rigidly connected to said feed in breakers; 61.51 a fuel cell, for demonstrating the future two directional flow of electricity coming from and going to a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and a fuel cell, showing how the system can not only charge the fuel cell but can use the fuel cell as a power storage device, rigidly connected to said feed in breakers; 61.52 a wind turbine, for showing the flow of electricity from one of the primary sources of renewable energy through a rectifier and then into the multi tap converter, a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said feed in breakers; 61.53 an auxiliary gas generator, for showing the flow of electricity going from the auxiliary gas generator through the rectifier and into the multi mode inverter, rigidly connected to said feed in breakers; 61.54 a dc bus, for demonstrating the two directional flow of electricity coming from and going to the multi tap converter and the high voltage dc bus, rigidly connected to said feed in breakers, and rigidly connected to said multi mode inverter/converter; 61.55 an inverter flow, for showing the flow from the high voltage do bus to the processor controlled multi mode inverter that converts the do power to 240 v 60 cycle ac output for use in the building or for sale to the utility electric service/grid; 61.56 a power control circuits, for showing the flow of electricity from the inverter to the processor controlled electronic power switching and regulation circuits, rigidly connected to said multi mode inverter/converter control panel, and rigidly connected to said electronic transfer isolation switch; 61.57 a micro processor control flow, for showing the two way communicating and controlling of the micro processor to and from the electronic power switching and regulation circuits, multi mode inverter, high voltage bus, multi tap converter and rectifier and all other processor controlled functions not listed, rigidly connected to said power control circuits, rigidly connected to said system programming port, rigidly connected to said RF module and internet module, rigidly connected to said multi mode inverter/converter control panel, and rigidly connected to said multi mode inverter/converter; 61.58 a RF and internet communication link, for showing the link between the micro processor to the internet communications link that automatically self connects to web management power control center for onsite load and energy management also showing the connection with the RF transceiver that sends and receives load management information to the remote load management modules; and 61.59 a Wi-Fi, wireless, Bluetooth and Zigbee enabled remote load management modules, for communicating and control the load management remote monitor/controller units that would be connected to key appliances, motors and systems within to be connected to key appliances, motors and systems within the building by an RF transmitter permitting continuous load and energy management of these devices by sending and receiving commands from the micro processor for the starting and stopping of the controlled devices, rigidly connected to said RF module and internet module.
 62. The system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management as recited in claim 61, further comprising: 62.1 an incases main power line when it is attached to building mast, for safety, whether the main power comes from underground or overhead there is some type of pipe covering it, rigidly connected to said meter receiver box, and rigidly connected to said power line.
 63. A system and method for single plug-in installation of a high voltage intelligent renewable energy grid-tied controller with wireless smart load management for simplifying the installation and in turn reducing the cost of that installation. Improving the performance by adding independent maximum power point tracking to the inverter. Making a system that is multi tap, multi mode so multiple input power devices can be used with a single inverter. Creating a wireless system for real time smart load management with an internet interface for system owner input, comprising: 63.1 a standard meter used in most residential and small commercial buildings existing meter, for measuring the flow of electricity in and out of a building, standard meter used in most residential and small commercial buildings; 63.2 a junction box between electric utility and main electric panel, houses the meter receiver and main cutoff of power from electric utility meter receiver box, for junction box between electric utility and main electric panel that houses the meter receiver and main cutoff of power from electric utility; 63.3 A main power line coming from utility power line, for transfer of electric power to and from the utility company; 63.4 an incases main power line when it is attached to building mast, for safety, whether the main power comes from underground or overhead there is some type of pipe covering it, rigidly connected to said power line, and rigidly connected to said meter receiver box; 63.5 a redirects or transfers main power line flow through grid-tie controller meter socket, can be used in standard meter receiver box, will work with both 100 and 200 amp service, is weather tight and fully serviceable meter jumper plug, for redirecting or transferring the main power line flow from the meter receiver box through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter receiver box and into the main service panel, rigidly connected to said meter receiver box; 63.6 a rated for 200 amps, stranded wire for maximum flexibility, soldered end caps for maximum current conductivity, all weather fittings and cover custom wire harness, for to facilitate the redirecting or transferring the main power line flow from the meter jumper plug through Intelligent Renewable Energy System grid-tie controller system meter socket and then back through the meter jumper plug and into the main service panel, rigidly connected to said meter jumper plug; 63.7 a work with existing meter, fully lockable isolated from other wiring, work as a standalone application on new construction, does not change the procedure or method for utilities to read the meter system meter socket, for creating a point or position on the Intelligent Renewable Energy System unit to relocate the existing meter too, once the power transfer is complete, rigidly connected to said custom wire harness, and rigidly connected to said existing meter; 63.8 a will work with either 100 or 200 amp service main breaker, for to create a main cutoff of power directly behind the existing meter once moved to the new location on the Intelligent Renewable Energy System, rigidly connected to said existing meter; 63.9 an automatically senses loss of power, automatically disconnects the house from utility power line, automatically reconnects the house to the utility power line, electronically synchronizes when reconnecting the utility power line, automatically displays state of the system electronic transfer isolation switch, for electronically sensing the loss of street power and disconnects the building from the utility power line. This permits the building to continue using the renewable generated or stored electricity without having electricity flow back to the utility power line. When the utility power line is restored the system electronically synchronizes and reconnects the building with the utility power line automatically, rigidly connected to said main breaker; 63.10 a processor controlled ac to dc rectifier, processor controlled dc to dc multi-tap converter, processor monitored independent maximum power point tracking, processor monitored high voltage dc bus, processor controlled multi mode inverter with 400 v dc input 240 v 60 cycle ac output, processor controlled electronic power switching and regulation circuits, programmable micro processor, DSP controller board, internet communications module, DSP controlled RF transceiver multi mode inverter/converter, for converting electrical energy simultaneously from multiple input sources whether they are DC or AC to DC, then converting that dc power to a usable 240 v clean 60 cycle ac power for processor controlled distribution into the building or out onto the utility power grid; 63.11 a multi mode inverter/converter control panel, for multi function keypad with LED display for programming features and checking system status, rigidly connected to said multi mode inverter/converter; 63.12 a Wi-Fi, wireless, Bluetooth and Zigbee enabled RF module and internet module, for communicating and controlling the load management remote monitor/controller units that would be connected to key appliances, motors and systems within the building permitting continuous load and energy management of these devices and communicating all what is happen to the internet personal interface; 63.13 a weather tight, lockable weather tight custom cabinet, for making the multi mode inverter/converter system weather tight for installation on the exterior of the building, rigidly connected to said system meter socket; 63.14 an aluminum alloy extrusion heat sink, for absorbing then dissipating the heat created by the systems electronic components, rigidly connected to said weather tight custom cabinet; 63.14 a zinc coated copper or aluminum energy input wiring bus, for mounting the intelligent Renewable Energy System necessary for adding energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 63.15 a custom cable with ground main energy source cable, for supplying input electric energy from the solar array and wind turbine that is remotely mounted on the roof of the building; 63.16 a ground fault, electronically monitored feed in breakers, for manually or electronically turning on and off energy supply elements such as gas generator, backup batteries, fuel cells or electric car power management system; 63.17 An USB, Ethernet system programing port, for system programming, onsite updates and maintenance by the certified installers; 63.18 a steel or aluminum mounting bracket, for mounting the system to the wall with sufficient stand off so the heat sink will function properly, rigidly connected to said weather tight custom cabinet; 63.19 a steel with rubber gasket water proof cap, for creating a weather tight cap over the pole mounting hole that converts the system to a standalone system for new construction installations; 63.20 A non-conductive plastic plug base, for creating the base for which all other elements of the meter jumper plug are mounted too; 63.21 A non-conductive plastic guide blocks, for guiding the meter jumper plug into place during an installation; 63.22 A non-conductive plastic blade seat, for creating a secure mounting position for the power blade elements; 63.23 A non-conducting plastic ground seat, for creating a secure mounting position for the ground block element; 63.24 a zinc plated copper, aluminum, or some other highly conductive metal ground transfer strap, for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.25 a zinc plated copper, aluminum, or some other highly conductive metal transfer strap screw, for connecting the ground transfer strap to the ground block for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.26 a zinc plated copper, aluminum, or some other highly conductive metal ground clamp, for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.27 a zinc plated copper, aluminum, or some other highly conductive metal clamp screw, for clamping the ground wire from the meter receiver box to the ground transfer strap for facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.28 a zinc plated copper, aluminum, or some other highly conductive metal ground block, for creating a connection point within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.29 a zinc plated copper, aluminum, or some other highly conductive metal ground block screw, for securing the wire within the ground screw block within the meter jumper plug for the custom wire harness to facilitating transferring the ground wire from the meter receiver box to the system meter socket; 63.30 a zinc plated copper, aluminum, or some other highly conductive metal power blade block, for facilitating within the meter jumper plug in transferring the power wire to and from the meter receiver box to and from the system meter socket; 63.31 a zinc plated copper, aluminum, or some other highly conductive metal blade block screw, for securing the wire in the power blade block within the meter jumper plug facilitating transferring the power wire to and from the meter receiver box to and from the system meter socket; 63.32 A non-conductive plastic meter plug cover, for creating a weather tight seal and cover over the components of the meter jumper plug; 63.33 A non-conductive plastic main wire port, for attaching the custom wire harness to the meter jumper plug; 63.34 A non-conductive plastic wire locking ring, for locking the custom wire harness to the meter jumper plug; 63.35 A metal cover screw, for securing the meter plugs cover to the plug base; 63.36 a copper, aluminum, or some other highly conductive metal ground wire, for transferring ground wire from the meter receiver box through meter plug to and from the service meter socket; 63.37 a copper, aluminum, or some other highly conductive metal power wire 1, for transferring power wire 1 from the meter receiver box through meter plug to and from the service meter socket; 63.38 a copper, aluminum, or some other highly conductive metal power wire 2, for transferring power wire 2 from the meter receiver box through meter plug to and from the service meter socket; 63.39 a copper, aluminum, or some other highly conductive metal power wire 3, for transferring power wire 3 from the meter receiver box through meter plug to and from the service meter socket; 63.40 a copper, aluminum, or some other highly conductive metal power wire 4, for transferring power wire 4 from the meter receiver box through meter plug to and from the service meter socket; 63.41 an electricity coming in from the street or electricity being sold back to the utility power grid utility electric service/grid access, for showing the transferring of electricity to and from the electric utility grid, rigidly connected to said power line; 63.42 A meter flow path, for demonstrating the two directional flows of electricity coming and going from the utility service through the meter jumper plug to the relocated meter in the system meter socket; 63.43 A disconnect flow path, for demonstrating the two directional flow of electricity coming and going from the relocated meter in the system meter socket to the service disconnect breaker; 63.44 An isolation flow, for demonstrating the two directional flows of electricity coming and going from the service disconnect breaker to the isolation switch; 63.45 A power switching flow, for demonstrating the two directional flow of electricity coming and going from the isolation switch to the electric power coming from the inverter system; 63.46 an electronic transfer flow, for demonstrating the one directional flow of electricity coming from the electronic transfer switch after it has electronically since a loss of power from the utility electric service/grid in turn isolating the grid from power being produced by the generation system; 63.47 A main service flow, for demonstrating the one directional flow of electricity coming from the utility service and the generation system through the meter jumper plug to the main service panel; 63.48 an electric car flow, for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an electric car, showing how the system can not only charge the electric car but can use the electric car as a power storage device, rigidly connected to said feed in breakers; 63.49 a solar cells, for showing the flow of electricity from one of the primary renewable energy sources to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said feed in breakers; 63.50 a battery storage, for demonstrating the two directional flow of electricity coming from and going to the processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and an battery storage system, showing how the system can not only charge the battery but can also use the battery as a power storage device, rigidly connected to said feed in breakers; 63.51 a fuel cell, for demonstrating the future two directional flow of electricity coming from and going to a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously and a fuel cell, showing how the system can not only charge the fuel cell but can use the fuel cell as a power storage device, rigidly connected to said feed in breakers; 63.52 a wind turbine, for showing the flow of electricity from one of the primary sources of renewable energy through a rectifier and then into the multi tap converter, a processor controlled multi tap converter with independent maximum power point tracking unique in its ability to take multiple energy input maximize that input simultaneously, rigidly connected to said feed in breakers; 63.53 an auxiliary gas generator, for showing the flow of electricity going from the auxiliary gas generator through the rectifier and into the multi mode inverter, rigidly connected to said feed in breakers; 63.54 a dc bus, for demonstrating the two directional flow of electricity coming from and going to the multi tap converter and the high voltage dc bus, rigidly connected to said feed in breakers, and rigidly connected to said multi mode inverter/converter; 63.55 an inverter flow, for showing the flow from the high voltage dc bus to the processor controlled multi mode inverter that converts the dc power to 240 v 60 cycle ac output for use in the building or for sale to the utility electric service/grid; 63.56 a power control circuits, for showing the flow of electricity from the inverter to the processor controlled electronic power switching and regulation circuits, rigidly connected to said multi mode inverter/converter control panel, and rigidly connected to said electronic transfer isolation switch; 63.57 a micro processor control flow, for showing the two way communicating and controlling of the micro processor to and from the electronic power switching and regulation circuits, multi mode inverter, high voltage bus, multi tap converter and rectifier and all other processor controlled functions not listed, rigidly connected to said power control circuits, rigidly connected to said system programming port, rigidly connected to said RF module and internet module, rigidly connected to said multi mode inverter/converter control panel, and rigidly connected to said multi mode inverter/converter; 63.58 a RF and internet communication link, for showing the link between the micro processor to the internet communications link that automatically self connects to web management power control center for onsite load and energy management also showing the connection with the RF transceiver that sends and receives load management information to the remote load management modules; and 63.59 a Wi-Fi, wireless, Bluetooth and Zigbee enabled remote load management modules, for communicating and control the load management remote monitor/controller units that would be connected to key appliances, motors and systems within to be connected to key appliances, motors and systems within the building by an RF transmitter permitting continuous load and energy management of these devices by sending and receiving commands from the micro processor for the starting and stopping of the controlled devices, rigidly connected to said RF module and internet module. 